« ForrigeFortsett »
the only solution of which in whole numbers is T= 3; F= 12; which gives E = 30, and S = 20.
This solid is the regular dodecahedron. (Geom. p. 161, &c.)
(68.) Similarly the regular solids all whose faces are squares are determined from the equation
8 - 2T. the only solution of which is T = 3, F= 6; which gives E = 12, S = 8. This is the cube. (Geom. p. 161.) (69.) For regular solids composed entirely of triangles, we have
6 - T
T F S Name of the solid.
3 4 6 4 Tetrahedron (70.) The materials of this treatise have been for the most part collected from Puissant, Traité de Géodésie, Delambre, Traité d'Astronomie (3 vols. 4to), and Legendre, Traité de Géométrie (Brewster's translation) to all of which works we refer the reader.
The following transformations, which, though not always possible, may often be used with advantage, have been suggested by a Member of the Committee. They may be very easily demonstrated. The formulæ are referred to, as in the work. (O). Assume tan. x = \tan. a tan. b cos. C. Then cos. A cos. b
Or assume tan. X = tan, a cos. C; cos.? x
LIBRARY OF USEFUL KNOWLEDGE.
Rev. S. W. WAUD, M.A. F. Ast. S.
FELLOW AND TUTOR OF MAGDALENE COLLEGE, CAMBRIDGE.
PUBLISHED UNDER THE SUPERINTENDENCE OF THE SOCIETY FOR
THE DIFFUSION OF USEFUL KNOWLEDGE.
APPLICATION OF ALGEBRA TO PLANE GEOMETRY.
1 1 2 3 4
1. Object of the Treatise
ab a Ib, Nab, Jab + cd, Na? +6, Na? +62 +c?, 12, NE
Na, Na + b, &c., the numerical unit is understood, and must be
14. Geometrical Problems may be divided into two classes, Determinate and Inde.
terminate : an example of each . 15. Rules which are generally useful in working Problems 16. To describe a square in a given triangle 17. In a right-angled triangle the lines drawn from the acute angles to the points of
bisection of the opposite sides are given, to find the triangle 18. To divide a straight line, so that the rectangle contained by the two parts may be equal to a given square. Remarks on the double roots
Page 19. Through a given point M equidistant from two perpendicular straight lines, to
11 draw a straight line of given length : various solutions 20. Through the same point to draw a line so that the sum of the squares upon the
two portions of it shall be equal to a given square 21. To find a triangle such that its three sides and perpendicular on the base are in
a continued progression
THE POINT AND STRAIGHT LINE.
19 19 20 21 22 22
22. Example of an Indeterminate Problem leading to an equation between two
quantities x and y. Definition of a locus 23. Division of equations into Algebraical and Transcendental 24. Some equations do not admit of loci 25. The position of a point in a plane determined. Equations to a point,
x = a, y=b; or (y-6)+ (x-2) = 0 26. Consideration of the negative sign as applied to the position of points in
Geometry 27, 28. The position of points on a plane, and examples 29. To find the distance between two points
D? =(a - a')? + (6 - b)2 30. The distance between two points referred to oblique axes
D2 = =(a – a')2 + (6 – 61)2 + 2(a – a') (b — b') cos. w 31, 33. The locus of the equation y=ax + b proved to be a straight line 34. Various positions of the locus corresponding to the Algebraic signs of a and b 35. The loci of the equations y=Ib, and y = 0 36. Examples of loci corresponding to equations of the first order 37, 39. Exceptions and general remarks 40. The equation to a straight line passing through a given point is
9 - 91=(2 – 31) 41. The equation to a straight line through two given points is
yı Y - Y1 =
- X2 42, To find the equation to a straight line through a given point, and bisecting a
finite portion of a given line 43. If y=ax+6 be a given straight line, the straight line parallel to it is
y = ax + 6 44. The co-ordinates of the intersection of two given lines y = ax + b, and
-6 all - ab
(«V-b) - (b"-4" b) + (du - 1) = 0. 45. If & and d) are the angles which two lines make with the axis of x,
wilt«) (1 tá?)